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HcalLedAnalysis Class Reference

#include <HcalLedAnalysis.h>

Classes

struct  CALIBBUNCH
 

Public Member Functions

 HcalLedAnalysis (const edm::ParameterSet &ps)
 Constructor. More...
 
void LedDone ()
 
void LedSampleAnalysis ()
 
void LedSetup (const std::string &m_outputFileROOT)
 
void processLedEvent (const HBHEDigiCollection &hbhe, const HODigiCollection &ho, const HFDigiCollection &hf, const HcalCalibDigiCollection &calib, const HcalDbService &cond)
 
 ~HcalLedAnalysis ()
 Destructor. More...
 

Private Types

typedef std::pair< TH1F *, std::pair< std::map< int, std::vector< double > >, std::vector< TH1F * > > > LEDBUNCH
 

Private Member Functions

float BinsizeCorr (float time)
 
void GetLedConst (std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT)
 
void LedHBHEHists (const HcalDetId &detid, const HBHEDataFrame &ledDigi, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT, const HcalDbService &cond)
 
void LedHFHists (const HcalDetId &detid, const HFDataFrame &ledDigi, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT, const HcalDbService &cond)
 
void LedHOHists (const HcalDetId &detid, const HODataFrame &ledDigi, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT, const HcalDbService &cond)
 
void LedTrendings (std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT)
 
void ProcessCalibEvent (int fiberChan, HcalCalibDetId calibId, const HcalCalibDataFrame &digi)
 
void SetupLEDHists (int id, const HcalDetId detid, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT)
 

Private Attributes

std::map< HcalCalibDetId, CALIBBUNCH >::iterator _meca
 
std::map< HcalDetId, std::map< int, float > >::iterator _meee
 
std::map< HcalDetId, std::map< int, LEDBUNCH > >::iterator _meol
 
std::map< HcalCalibDetId, CALIBBUNCHcalibHists
 
int evt
 
int evt_curr
 
struct {
   TH1F *   ALLLEDS
 
   TH1F *   CHI2
 
   TH1F *   LEDMEAN
 
   TH1F *   LEDRMS
 
   std::map< HcalDetId, std::map< int, LEDBUNCH > >   LEDTRENDS
 
hbHists
 
struct {
   TH1F *   ALLLEDS
 
   TH1F *   CHI2
 
   TH1F *   LEDMEAN
 
   TH1F *   LEDRMS
 
   std::map< HcalDetId, std::map< int, LEDBUNCH > >   LEDTRENDS
 
hfHists
 
struct {
   TH1F *   ALLLEDS
 
   TH1F *   CHI2
 
   TH1F *   LEDMEAN
 
   TH1F *   LEDRMS
 
   std::map< HcalDetId, std::map< int, LEDBUNCH > >   LEDTRENDS
 
hoHists
 
std::map< HcalDetId, std::map< int, float > > m_AllPedVals
 
const HcalQIECoderm_coder
 
int m_endTS
 
TFile * m_file
 
int m_fitflag
 
int m_hiSaveflag
 
std::ofstream m_logFile
 
int m_nevtsample
 
std::ofstream m_outFile
 
std::string m_outputFileROOT
 
std::string m_outputFileText
 
std::string m_outputFileX
 
std::ofstream m_outputFileXML
 
const HcalPedestalm_ped
 
const HcalQIEShapem_shape
 
int m_startTS
 
bool m_usecalib
 
int sample
 
std::vector< bool > state
 

Detailed Description

Definition at line 32 of file HcalLedAnalysis.h.

Member Typedef Documentation

typedef std::pair<TH1F*,std::pair<std::map<int, std::vector<double> >,std::vector<TH1F*> > > HcalLedAnalysis::LEDBUNCH
private

Definition at line 68 of file HcalLedAnalysis.h.

Constructor & Destructor Documentation

HcalLedAnalysis::HcalLedAnalysis ( const edm::ParameterSet ps)

Constructor.

Definition at line 12 of file HcalLedAnalysis.cc.

References gather_cfg::cout, edm::ParameterSet::getUntrackedParameter(), gen::k, convertSQLitetoXML_cfg::output, and simplePhotonAnalyzer_cfi::sample.

13 {
14  // init
15 
16  m_coder = nullptr;
17  m_ped = nullptr;
18  m_shape = nullptr;
19  evt=0;
20  sample=0;
21  m_file=nullptr;
22  // output files
23  for(int k=0;k<4;k++) state.push_back(true); // 4 cap-ids (do we care?)
24  m_outputFileText = ps.getUntrackedParameter<string>("outputFileText", "");
25  m_outputFileX = ps.getUntrackedParameter<string>("outputFileXML","");
26  if ( !m_outputFileText.empty() ) {
27  cout << "Hcal LED results will be saved to " << m_outputFileText.c_str() << endl;
28  m_outFile.open(m_outputFileText.c_str());
29  }
30  m_outputFileROOT = ps.getUntrackedParameter<string>("outputFileHist", "");
31  if ( !m_outputFileROOT.empty() ) {
32  cout << "Hcal LED histograms will be saved to " << m_outputFileROOT.c_str() << endl;
33  }
34 
35  m_nevtsample = ps.getUntrackedParameter<int>("nevtsample",9999999);
36  if(m_nevtsample<1)m_nevtsample=9999999;
37  m_hiSaveflag = ps.getUntrackedParameter<int>("hiSaveflag",0);
40  m_fitflag = ps.getUntrackedParameter<int>("analysisflag",2);
41  if(m_fitflag<0)m_fitflag=0;
42  if(m_fitflag>4)m_fitflag=4;
43  m_startTS = ps.getUntrackedParameter<int>("firstTS", 0);
44  if(m_startTS<0) m_startTS=0;
45  m_endTS = ps.getUntrackedParameter<int>("lastTS", 9);
46  m_usecalib = ps.getUntrackedParameter<bool>("usecalib",false);
47  m_logFile.open("HcalLedAnalysis.log");
48 
49  int runNum = ps.getUntrackedParameter<int>("runNumber",999999);
50 
51  // histogram booking
52  hbHists.ALLLEDS = new TH1F("HBHE All LEDs","HB/HE All Leds",10,0,9);
53  hbHists.LEDRMS= new TH1F("HBHE All LED RMS","HB/HE All LED RMS",100,0,3);
54  hbHists.LEDMEAN= new TH1F("HBHE All LED Means","HB/HE All LED Means",100,0,9);
55  hbHists.CHI2= new TH1F("HBHE Chi2 by ndf for Landau fit","HB/HE Chi2/ndf Landau",200,0.,50.);
56 
57  hoHists.ALLLEDS = new TH1F("HO All LEDs","HO All Leds",10,0,9);
58  hoHists.LEDRMS= new TH1F("HO All LED RMS","HO All LED RMS",100,0,3);
59  hoHists.LEDMEAN= new TH1F("HO All LED Means","HO All LED Means",100,0,9);
60  hoHists.CHI2= new TH1F("HO Chi2 by ndf for Landau fit","HO Chi2/ndf Landau",200,0.,50.);
61 
62  hfHists.ALLLEDS = new TH1F("HF All LEDs","HF All Leds",10,0,9);
63  hfHists.LEDRMS= new TH1F("HF All LED RMS","HF All LED RMS",100,0,3);
64  hfHists.LEDMEAN= new TH1F("HF All LED Means","HF All LED Means",100,0,9);
65  hfHists.CHI2= new TH1F("HF Chi2 by ndf for Landau fit","HF Chi2/ndf Landau",200,0.,50.);
66 
67  char output[100]{0};
68 
69  //XML file header
70  m_outputFileXML.open(m_outputFileX.c_str());
71 
72  m_outputFileXML << "<?xml version='1.0' encoding='UTF-8'?>" << endl;
73 
74  m_outputFileXML << "<ROOT>" << endl;
75 
76  m_outputFileXML << " <HEADER>" << endl;
77 
78  m_outputFileXML << " <TYPE>" << endl;
79 
80  m_outputFileXML << " <EXTENSION_TABLE_NAME>HCAL_LED_TIMING</EXTENSION_TABLE_NAME>" << endl;
81 
82  m_outputFileXML << " <NAME>HCAL LED Timing</NAME>" << endl;
83 
84  m_outputFileXML << " </TYPE>" << endl;
85 
86  m_outputFileXML << " <RUN>" << endl;
87 
88  m_outputFileXML << " <RUN_TYPE>hcal-led-timing-test</RUN_TYPE>" << endl;
89 
90  snprintf(output, sizeof output, " <RUN_NUMBER>%06i</RUN_NUMBER>", runNum);
91  m_outputFileXML << output << endl;
92 
93  m_outputFileXML << " <RUN_BEGIN_TIMESTAMP>2007-07-09 00:00:00.0</RUN_BEGIN_TIMESTAMP>" << endl;
94 
95  m_outputFileXML << " <COMMENT_DESCRIPTION></COMMENT_DESCRIPTION>" << endl;
96 
97  m_outputFileXML << " </RUN>" << endl;
98 
99  m_outputFileXML << " </HEADER>" << endl;
100 
101  m_outputFileXML << "<!-- Tags secton -->" << endl;
102 
103  m_outputFileXML << " <ELEMENTS>" << endl;
104 
105  m_outputFileXML << " <DATA_SET id='-1'/>" << endl;
106 
107  m_outputFileXML << " <IOV id='1'>" << endl;
108 
109  m_outputFileXML << " <INTERVAL_OF_VALIDITY_BEGIN>2147483647</INTERVAL_OF_VALIDITY_BEGIN>" << endl;
110 
111  m_outputFileXML << " <INTERVAL_OF_VALIDITY_END>0</INTERVAL_OF_VALIDITY_END>" << endl;
112 
113  m_outputFileXML << " </IOV>" << endl;
114 
115  m_outputFileXML << " <TAG id='2' mode='auto'>" << endl;
116 
117  snprintf(output, sizeof output, " <TAG_NAME>laser_led_%06i<TAG_NAME>", runNum);
118  m_outputFileXML << output << endl;
119 
120  m_outputFileXML << " <DETECTOR_NAME>HCAL</DETECTOR_NAME>" << endl;
121 
122  m_outputFileXML << " <COMMENT_DESCRIPTION></COMMENT_DESCRIPTION>" << endl;
123 
124  m_outputFileXML << " </TAG>" << endl;
125 
126  m_outputFileXML << " </ELEMENTS>" << endl;
127 
128  m_outputFileXML << " <MAPS>" << endl;
129 
130  m_outputFileXML << " <TAG idref ='2'>" << endl;
131 
132  m_outputFileXML << " <IOV idref='1'>" << endl;
133 
134  m_outputFileXML << " <DATA_SET idref='-1' />" << endl;
135 
136  m_outputFileXML << " </IOV>" << endl;
137 
138  m_outputFileXML << " </TAG>" << endl;
139 
140  m_outputFileXML << " </MAPS>" << endl;
141 
142 }
T getUntrackedParameter(std::string const &, T const &) const
std::vector< bool > state
std::ofstream m_logFile
std::string m_outputFileROOT
const HcalPedestal * m_ped
struct HcalLedAnalysis::@56 hbHists
std::string m_outputFileX
const HcalQIECoder * m_coder
struct HcalLedAnalysis::@56 hoHists
std::ofstream m_outputFileXML
int k[5][pyjets_maxn]
std::ofstream m_outFile
const HcalQIEShape * m_shape
struct HcalLedAnalysis::@56 hfHists
std::string m_outputFileText
HcalLedAnalysis::~HcalLedAnalysis ( )

Destructor.

All done, clean up!!

Definition at line 145 of file HcalLedAnalysis.cc.

References mps_fire::i.

145  {
147  for(_meol=hbHists.LEDTRENDS.begin(); _meol!=hbHists.LEDTRENDS.end(); _meol++){
148  for(int i=0; i<15; i++) _meol->second[i].first->Delete();
149  }
150  for(_meol=hoHists.LEDTRENDS.begin(); _meol!=hoHists.LEDTRENDS.end(); _meol++){
151  for(int i=0; i<15; i++) _meol->second[i].first->Delete();
152  }
153  for(_meol=hfHists.LEDTRENDS.begin(); _meol!=hfHists.LEDTRENDS.end(); _meol++){
154  for(int i=0; i<15; i++) _meol->second[i].first->Delete();
155  }
156  hbHists.ALLLEDS->Delete();
157  hbHists.LEDRMS->Delete();
158  hbHists.LEDMEAN->Delete();
159  hbHists.CHI2->Delete();
160 
161  hoHists.ALLLEDS->Delete();
162  hoHists.LEDRMS->Delete();
163  hoHists.LEDMEAN->Delete();
164  hoHists.CHI2->Delete();
165 
166  hfHists.ALLLEDS->Delete();
167  hfHists.LEDRMS->Delete();
168  hfHists.LEDMEAN->Delete();
169  hfHists.CHI2->Delete();
170 }
struct HcalLedAnalysis::@56 hbHists
struct HcalLedAnalysis::@56 hoHists
struct HcalLedAnalysis::@56 hfHists
std::map< HcalDetId, std::map< int, LEDBUNCH > >::iterator _meol

Member Function Documentation

float HcalLedAnalysis::BinsizeCorr ( float  time)
private

Definition at line 850 of file HcalLedAnalysis.cc.

References mps_fire::i, and createfilelist::int.

850  {
851 
852 // this is the bin size correction to be applied for laser data (from Andy),
853 // it comes from a pulse shape measured from TB04 data (from Jordan)
854 // This should eventually be replaced with the more thorough treatment from Phil
855 
856  float corrtime=0.;
857  static const float tstrue[32]={0.003, 0.03425, 0.06548, 0.09675, 0.128,
858  0.15925, 0.1905, 0.22175, 0.253, 0.28425, 0.3155, 0.34675, 0.378, 0.40925,
859  0.4405, 0.47175, 0.503, 0.53425, 0.5655, 0.59675, 0.628, 0.65925, 0.6905,
860  0.72175, 0.753, 0.78425, 0.8155, 0.84675, 0.878, 0.90925, 0.9405, 0.97175};
861  static const float tsreco[32]={-0.00422, 0.01815, 0.04409, 0.07346, 0.09799,
862  0.12192, 0.15072, 0.18158, 0.21397, 0.24865, 0.28448, 0.31973, 0.35449,
863  0.39208, 0.43282, 0.47244, 0.5105, 0.55008, 0.58827, 0.62828, 0.6717, 0.70966,
864  0.74086, 0.77496, 0.80843, 0.83472, 0.86044, 0.8843, 0.90674, 0.92982,
865  0.95072, 0.9726};
866 
867  int inttime=(int)time;
868  float restime=time-inttime;
869  for(int i=0; i<=32; i++) {
870  float lolim=0.; float uplim=1.; float tsdown; float tsup;
871  if(i>0){
872  lolim=tsreco[i-1];
873  tsdown=tstrue[i-1];
874  }
875  else tsdown=tstrue[31]-1.;
876  if(i<32){
877  uplim=tsreco[i];
878  tsup=tstrue[i];
879  }
880  else tsup=tstrue[0]+1.;
881  if(restime>=lolim && restime<uplim){
882  corrtime=(tsdown*(uplim-restime)+tsup*(restime-lolim)) / (uplim-lolim);
883  }
884  }
885  corrtime+=inttime;
886 
887  return corrtime;
888 }
void HcalLedAnalysis::GetLedConst ( std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT)
private

Definition at line 208 of file HcalLedAnalysis.cc.

References HcalDetId::depth(), mps_fire::i, HcalDetId::ietaAbs(), HcalDetId::iphi(), convertSQLitetoXML_cfg::output, DetId::rawId(), mathSSE::sqrt(), HcalDetId::subdet(), and HcalDetId::zside().

208  {
209  double time2=0; double time1=0; double time3=0; double time4=0;
210  double dtime2=0; double dtime1=0; double dtime3=0; double dtime4=0;
211  char output[256]{0};
212 
213  if (m_outputFileText!=""){
214  if(m_fitflag==0 || m_fitflag==2) m_outFile<<"Det Eta,Phi,D Mean Error"<<std::endl;
215  else if(m_fitflag==1 || m_fitflag==3) m_outFile<<"Det Eta,Phi,D Peak Error"<<std::endl;
216  else if(m_fitflag==4) m_outFile<<"Det Eta,Phi,D Mean Error Peak Error MeanEv Error PeakEv Error"<<std::endl;
217  }
218  for(_meol=toolT.begin(); _meol!=toolT.end(); _meol++){
219 // scale the LED pulse to 1 event
220  _meol->second[10].first->Scale(1./evt_curr);
221  if(m_fitflag==0 || m_fitflag==4){
222  time1 = _meol->second[10].first->GetMean();
223  dtime1 = _meol->second[10].first->GetRMS()/sqrt((float)evt_curr*(m_endTS-m_startTS+1));
224  }
225  if(m_fitflag==1 || m_fitflag==4){
226 // put proper errors
227  for(int j=0; j<10; j++) _meol->second[10].first->SetBinError(j+1,_meol->second[j].first->GetRMS()/sqrt((float)evt_curr));
228  }
229  if(m_fitflag==1 || m_fitflag==3 || m_fitflag==4){
230  _meol->second[10].first->Fit("landau","Q");
231 // _meol->second[10].first->Fit("gaus","Q");
232  TF1 *fit = _meol->second[10].first->GetFunction("landau");
233 // TF1 *fit = _meol->second[10].first->GetFunction("gaus");
234  time2=fit->GetParameter(1);
235  dtime2=fit->GetParError(1);
236  }
237  if(m_fitflag==2 || m_fitflag==4){
238  time3 = _meol->second[12].first->GetMean();
239  dtime3 = _meol->second[12].first->GetRMS()/sqrt((float)_meol->second[12].first->GetEntries());
240  }
241  if(m_fitflag==3 || m_fitflag==4){
242  time4 = _meol->second[13].first->GetMean();
243  dtime4 = _meol->second[13].first->GetRMS()/sqrt((float)_meol->second[13].first->GetEntries());
244  }
245  for (int i=0; i<10; i++){
246  _meol->second[i].first->GetXaxis()->SetTitle("Pulse height (fC)");
247  _meol->second[i].first->GetYaxis()->SetTitle("Counts");
248 // if(m_hiSaveflag>0)_meol->second[i].first->Write();
249  }
250  _meol->second[10].first->GetXaxis()->SetTitle("Time slice");
251  _meol->second[10].first->GetYaxis()->SetTitle("Averaged pulse (fC)");
252  if(m_hiSaveflag>0)_meol->second[10].first->Write();
253  _meol->second[10].second.first[0].push_back(time1);
254  _meol->second[10].second.first[1].push_back(dtime1);
255  _meol->second[11].second.first[0].push_back(time2);
256  _meol->second[11].second.first[1].push_back(dtime2);
257  _meol->second[12].first->GetXaxis()->SetTitle("Mean TS");
258  _meol->second[12].first->GetYaxis()->SetTitle("Counts");
259  if(m_fitflag==2 && m_hiSaveflag>0)_meol->second[12].first->Write();
260  _meol->second[12].second.first[0].push_back(time3);
261  _meol->second[12].second.first[1].push_back(dtime3);
262  _meol->second[13].first->GetXaxis()->SetTitle("Peak TS");
263  _meol->second[13].first->GetYaxis()->SetTitle("Counts");
264  if(m_fitflag>2 && m_hiSaveflag>0)_meol->second[13].first->Write();
265  _meol->second[13].second.first[0].push_back(time4);
266  _meol->second[13].second.first[1].push_back(dtime4);
267  _meol->second[14].first->GetXaxis()->SetTitle("Peak TS error");
268  _meol->second[14].first->GetYaxis()->SetTitle("Counts");
269  if(m_fitflag>2 && m_hiSaveflag>0)_meol->second[14].first->Write();
270  _meol->second[15].first->GetXaxis()->SetTitle("Chi2/NDF");
271  _meol->second[15].first->GetYaxis()->SetTitle("Counts");
272  if(m_fitflag>2 && m_hiSaveflag>0)_meol->second[15].first->Write();
273  _meol->second[16].first->GetXaxis()->SetTitle("Integrated Signal");
274  _meol->second[16].first->Write();
275 
276 
277 // Ascii printout (need to modify to include new info)
278  HcalDetId detid = _meol->first;
279 
280  if (m_outputFileText!=""){
281  if(m_fitflag==0) {
282  m_outFile<<detid<<" "<<time1<<" "<<dtime1<<std::endl;
283  m_outputFileXML << " <DATA_SET>" << endl;
284  m_outputFileXML << " <VERSION>version:1</VERSION>" << endl;
285  m_outputFileXML << " <CHANNEL>" << endl;
286  m_outputFileXML << " <EXTENSION_TABLE_NAME>HCAL_CHANNELS</EXTENSION_TABLE_NAME>" << endl;
287  snprintf(output, sizeof output, " <ETA>%2i</ETA>", detid.ietaAbs() );
288  m_outputFileXML << output << endl;
289  snprintf(output, sizeof output, " <PHI>%2i</PHI>", detid.iphi() );
290  m_outputFileXML << output << endl;
291  snprintf(output, sizeof output, " <DEPTH>%2i</DEPTH>", detid.depth() );
292  m_outputFileXML << output << endl;
293  snprintf(output, sizeof output, " <Z>%2i</Z>", detid.zside() );
294  m_outputFileXML << output << endl;
295 
296  if(detid.subdet() == 1) m_outputFileXML << " <DETECTOR_NAME>HB</DETECTOR_NAME>" << endl;
297  if(detid.subdet() == 2) m_outputFileXML << " <DETECTOR_NAME>HE</DETECTOR_NAME>" << endl;
298  if(detid.subdet() == 3) m_outputFileXML << " <DETECTOR_NAME>HO</DETECTOR_NAME>" << endl;
299  if(detid.subdet() == 4) m_outputFileXML << " <DETECTOR_NAME>HF</DETECTOR_NAME>" << endl;
300  snprintf(output, sizeof output, " <HCAL_CHANNEL_ID>%10i</HCAL_CHANNEL_ID>", detid.rawId() );
301  m_outputFileXML << output << endl;
302  m_outputFileXML << " </CHANNEL>" << endl;
303  m_outputFileXML << " <DATA>" << endl;
304  snprintf(output, sizeof output, " <MEAN_TIME>%7f</MEAN_TIME>", time1);
305  m_outputFileXML << output << endl;
306  m_outputFileXML << " <OFFSET_TIME> 0</OFFSET_TIME>" << endl;
307  snprintf(output, sizeof output, " <ERROR_STAT>%7f</ERROR_STAT>", dtime1);
308  m_outputFileXML << output << endl;
309  snprintf(output, sizeof output, " <ANALYSIS_FLAG>%2i</ANALYSIS_FLAG>", m_fitflag+1);
310  m_outputFileXML << output << endl;
311  m_outputFileXML << " <STATUS_WORD> 0</STATUS_WORD>" << endl;
312  m_outputFileXML << " </DATA>" << endl;
313  m_outputFileXML << " </DATA_SET>" << endl;
314 
315  }
316  else if(m_fitflag==1){
317  m_outFile<<detid<<" "<<time2<<" "<<dtime2<<std::endl;
318  m_outputFileXML << " <DATA_SET>" << endl;
319  m_outputFileXML << " <VERSION>version:1</VERSION>" << endl;
320  m_outputFileXML << " <CHANNEL>" << endl;
321  m_outputFileXML << " <EXTENSION_TABLE_NAME>HCAL_CHANNELS</EXTENSION_TABLE_NAME>" << endl;
322  snprintf(output, sizeof output, " <ETA>%2i</ETA>", detid.ietaAbs() );
323  m_outputFileXML << output << endl;
324  snprintf(output, sizeof output, " <PHI>%2i</PHI>", detid.iphi() );
325  m_outputFileXML << output << endl;
326  snprintf(output, sizeof output, " <DEPTH>%2i</DEPTH>", detid.depth() );
327  m_outputFileXML << output << endl;
328  snprintf(output, sizeof output, " <Z>%2i</Z>", detid.zside() );
329  m_outputFileXML << output << endl;
330  if(detid.subdet() == 1) m_outputFileXML << " <DETECTOR_NAME>HB</DETECTOR_NAME>"<< endl;
331  if(detid.subdet() == 2) m_outputFileXML << " <DETECTOR_NAME>HE</DETECTOR_NAME>"<< endl;
332  if(detid.subdet() == 3) m_outputFileXML << " <DETECTOR_NAME>HO</DETECTOR_NAME>"<< endl;
333  if(detid.subdet() == 4) m_outputFileXML << " <DETECTOR_NAME>HF</DETECTOR_NAME>"<< endl;
334  snprintf(output, sizeof output, " <HCAL_CHANNEL_ID>%10i</HCAL_CHANNEL_ID>", detid.rawId() );
335  m_outputFileXML << output << endl;
336  m_outputFileXML << " </CHANNEL>" << endl;
337  m_outputFileXML << " <DATA>" << endl;
338  snprintf(output, sizeof output, " <MEAN_TIME>%7f</MEAN_TIME>", time2);
339  m_outputFileXML << output << endl;
340  m_outputFileXML << " <OFFSET_TIME> 0</OFFSET_TIME>" << endl;
341  snprintf(output, sizeof output, " <ERROR_STAT>%7f</ERROR_STAT>", dtime2);
342  m_outputFileXML << output << endl;
343  snprintf(output, sizeof output, " <ANALYSIS_FLAG>%2i</ANALYSIS_FLAG>", m_fitflag+1);
344  m_outputFileXML << output << endl;
345  m_outputFileXML << " <STATUS_WORD> 0</STATUS_WORD>" << endl;
346  m_outputFileXML << " </DATA>" << endl;
347  m_outputFileXML << " </DATA_SET>" << endl;
348  }
349 
350  else if(m_fitflag==2){
351  m_outFile<<detid<<" "<<time3<<" "<<dtime3<<std::endl;
352  m_outputFileXML << " <DATA_SET>" << endl;
353  m_outputFileXML << " <VERSION>version:1</VERSION>" << endl;
354  m_outputFileXML << " <CHANNEL>" << endl;
355  m_outputFileXML << " <EXTENSION_TABLE_NAME>HCAL_CHANNELS</EXTENSION_TABLE_NAME>" << endl;
356  snprintf(output, sizeof output, " <ETA>%2i</ETA>", detid.ietaAbs() );
357  m_outputFileXML << output << endl;
358  snprintf(output, sizeof output, " <PHI>%2i</PHI>", detid.iphi() );
359  m_outputFileXML << output << endl;
360  snprintf(output, sizeof output, " <DEPTH>%2i</DEPTH>", detid.depth() );
361  m_outputFileXML << output << endl;
362  snprintf(output, sizeof output, " <Z>%2i</Z>", detid.zside() );
363  m_outputFileXML << output << endl;
364  if(detid.subdet() == 1) m_outputFileXML << " <DETECTOR_NAME>HB</DETECTOR_NAME>" << endl;
365  if(detid.subdet() == 2) m_outputFileXML << " <DETECTOR_NAME>HE</DETECTOR_NAME>" << endl;
366  if(detid.subdet() == 3) m_outputFileXML << " <DETECTOR_NAME>HO</DETECTOR_NAME>" << endl;
367  if(detid.subdet() == 4) m_outputFileXML << " <DETECTOR_NAME>HF</DETECTOR_NAME>" << endl;
368  snprintf(output, sizeof output, " <HCAL_CHANNEL_ID>%10i</HCAL_CHANNEL_ID>", detid.rawId() );
369  m_outputFileXML << output << endl;
370  m_outputFileXML << " </CHANNEL>" << endl;
371  m_outputFileXML << " <DATA>" << endl;
372  snprintf(output, sizeof output, " <MEAN_TIME>%7f</MEAN_TIME>", time3);
373  m_outputFileXML << output << endl;
374  m_outputFileXML << " <OFFSET_TIME> 0</OFFSET_TIME>" << endl;
375  snprintf(output, sizeof output, " <ERROR_STAT>%7f</ERROR_STAT>", dtime3);
376  m_outputFileXML << output << endl;
377  snprintf(output, sizeof output, " <ANALYSIS_FLAG>%2i</ANALYSIS_FLAG>", m_fitflag+1);
378  m_outputFileXML << output << endl;
379  m_outputFileXML << " <STATUS_WORD> 0</STATUS_WORD>" << endl;
380  m_outputFileXML << " </DATA>" << endl;
381  m_outputFileXML << " </DATA_SET>" << endl;
382  }
383  else if(m_fitflag==3){
384  m_outFile<<detid<<" "<<time4<<" "<<dtime4<<std::endl;
385  m_outputFileXML << " <DATA_SET>" << endl;
386  m_outputFileXML <<" <VERSION>version:1</VERSION>" << endl;
387  m_outputFileXML << " <CHANNEL>" << endl;
388  m_outputFileXML << " <EXTENSION_TABLE_NAME>HCAL_CHANNELS</EXTENSION_TABLE_NAME>" << endl;
389  snprintf(output, sizeof output, " <ETA>%2i</ETA>", detid.ietaAbs() );
390  m_outputFileXML << output << endl;
391  snprintf(output, sizeof output, " <PHI>%2i</PHI>", detid.iphi() );
392  m_outputFileXML << output << endl;
393  snprintf(output, sizeof output," <DEPTH>%2i</DEPTH>", detid.depth() );
394  m_outputFileXML << output << endl;
395  sprintf(output, " <Z>%2i</Z>", detid.zside() );
396  m_outputFileXML << output << endl;
397  if(detid.subdet() == 1) m_outputFileXML <<" <DETECTOR_NAME>HB</DETECTOR_NAME>" << endl;
398  if(detid.subdet() == 2) m_outputFileXML <<" <DETECTOR_NAME>HE</DETECTOR_NAME>" << endl;
399  if(detid.subdet() == 3) m_outputFileXML <<" <DETECTOR_NAME>HO</DETECTOR_NAME>" << endl;
400  if(detid.subdet() == 4) m_outputFileXML <<" <DETECTOR_NAME>HF</DETECTOR_NAME>" << endl;
401  snprintf(output, sizeof output, " <HCAL_CHANNEL_ID>%10i</HCAL_CHANNEL_ID>", detid.rawId() );
402  m_outputFileXML << output << endl;
403  m_outputFileXML << " </CHANNEL>" << endl;
404  m_outputFileXML << " <DATA>" << endl;
405  snprintf(output, sizeof output, " <MEAN_TIME>%7f</MEAN_TIME>", time4);
406  m_outputFileXML << output << endl;
407  m_outputFileXML << " <OFFSET_TIME> 0</OFFSET_TIME>" << endl;
408  snprintf(output, sizeof output, " <ERROR_STAT>%7f</ERROR_STAT>", dtime4);
409  m_outputFileXML << output << endl;
410  snprintf(output, sizeof output, " <ANALYSIS_FLAG>%2i</ANALYSIS_FLAG>", m_fitflag+1);
411  m_outputFileXML << output << endl;
412  m_outputFileXML << " <STATUS_WORD> 0</STATUS_WORD>" << endl;
413  m_outputFileXML << " </DATA>" << endl;
414  m_outputFileXML << " </DATA_SET>" << endl;
415  }
416 
417  else if(m_fitflag==4){
418  m_outFile<<detid<<" "<<time1<<" "<<dtime1<<" "<<time2<<" "<<dtime2<<" "<<time3<<" "<<dtime3<<" "<<time4<<" "<<dtime4<<std::endl;
419  }
420  }
421  }
422 }
HcalSubdetector subdet() const
get the subdetector
Definition: HcalDetId.h:49
int zside() const
get the z-side of the cell (1/-1)
Definition: HcalDetId.cc:93
uint32_t rawId() const
get the raw id
Definition: DetId.h:44
int depth() const
get the tower depth
Definition: HcalDetId.cc:108
T sqrt(T t)
Definition: SSEVec.h:18
std::ofstream m_outputFileXML
int ietaAbs() const
get the absolute value of the cell ieta
Definition: HcalDetId.cc:98
int iphi() const
get the cell iphi
Definition: HcalDetId.cc:103
std::ofstream m_outFile
std::string m_outputFileText
std::map< HcalDetId, std::map< int, LEDBUNCH > >::iterator _meol
void HcalLedAnalysis::LedDone ( )

Definition at line 473 of file HcalLedAnalysis.cc.

References gather_cfg::cout, and simplePhotonAnalyzer_cfi::sample.

474 {
475 
476 // First process the last sample (remaining events).
478 
479 // Now do the end of run analysis: trending histos
480  if(sample>1 && m_fitflag!=4){
481  m_file->cd();
482  m_file->cd("HBHE");
483  LedTrendings(hbHists.LEDTRENDS);
484  m_file->cd();
485  m_file->cd("HO");
486  LedTrendings(hoHists.LEDTRENDS);
487  m_file->cd();
488  m_file->cd("HF");
489  LedTrendings(hfHists.LEDTRENDS);
490  }
491 
492  // Write other histograms.
493  // HB
494  m_file->cd();
495  m_file->cd("HBHE");
496  hbHists.ALLLEDS->Write();
497  hbHists.LEDRMS->Write();
498  hbHists.LEDMEAN->Write();
499  // HO
500  m_file->cd();
501  m_file->cd("HO");
502  hoHists.ALLLEDS->Write();
503  hoHists.LEDRMS->Write();
504  hoHists.LEDMEAN->Write();
505  // HF
506  m_file->cd();
507  m_file->cd("HF");
508  hfHists.ALLLEDS->Write();
509  hfHists.LEDRMS->Write();
510  hfHists.LEDMEAN->Write();
511  // Calib
512  m_file->cd();
513  m_file->cd("Calib");
514  for(_meca=calibHists.begin(); _meca!=calibHists.end(); _meca++){
515  _meca->second.avePulse->Write();
516  _meca->second.integPulse->Write();
517  }
518 
519  // Write the histo file and close it
520 // m_file->Write();
521  m_file->Close();
522  cout << "Hcal histograms written to " << m_outputFileROOT.c_str() << endl;
523 }
std::map< HcalCalibDetId, CALIBBUNCH > calibHists
std::string m_outputFileROOT
struct HcalLedAnalysis::@56 hbHists
std::map< HcalCalibDetId, CALIBBUNCH >::iterator _meca
struct HcalLedAnalysis::@56 hoHists
struct HcalLedAnalysis::@56 hfHists
void LedTrendings(std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT)
void HcalLedAnalysis::LedHBHEHists ( const HcalDetId detid,
const HBHEDataFrame ledDigi,
std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT,
const HcalDbService cond 
)
private

Definition at line 646 of file HcalLedAnalysis.cc.

References ecalMGPA::adc(), plotBeamSpotDB::first, HcalDbService::getHcalCoder(), HcalDbService::getHcalShape(), HcalDbService::getPedestal(), mps_fire::i, createfilelist::int, gen::k, and HBHEDataFrame::size().

646  {
647 
648  map<int,LEDBUNCH> _mei;
649  _meol = toolT.find(detid);
650  _mei = _meol->second;
651 
652  // Reset the histos if we're at the end of a 'bunch'
653  if((evt-1)%m_nevtsample==0 && state[0]){
654  for(int k=0; k<(int)state.size();k++) state[k]=false;
655  for(int i=0; i<16; i++) _mei[i].first->Reset();
656  }
657 
658  // Most of this is borrowed from HcalSimpleReconstructor, so thanks Jeremy/Phil
659 
660 
661  // int maxTS = -1;
662  float max_fC = 0;
663  float ta = 0;
664  m_coder = cond.getHcalCoder(detid);
665  m_ped = cond.getPedestal(detid);
666  m_shape = cond.getHcalShape(m_coder);
667  for (int TS = m_startTS; TS < m_endTS && TS < ledDigi.size(); TS++){
668  int capid = ledDigi[TS].capid();
669  int adc = ledDigi[TS].adc();
670  double fC = m_coder->charge(*m_shape,adc,capid);
671  ta = (fC - m_ped->getValue(capid));
672  //cout << "DetID: " << detid << " CapID: " << capid << " ADC: " << adc << " fC: " << fC << endl;
673  _mei[TS].first->Fill(ta);
674  _mei[10].first->AddBinContent(TS+1,ta); // This is average pulse, could probably do better (Profile?)
675  if(m_fitflag>1){
676  if(TS==m_startTS)_mei[11].first->Reset();
677  _mei[11].first->SetBinContent(TS+1,ta);
678  }
679  // keep track of max TS and max amplitude (in fC)
680  if (ta > max_fC){
681  max_fC = ta;
682  // maxTS = TS;
683  }
684  }
685 
686  // Now we have a sample with pedestals subtracted and in units of fC
687  // If we are using a weighted mean (m_fitflag = 2) to extraxt timing
688  // we now want to use Phil's timing correction. This is not necessary
689  // if we are performing a Landau fit (m_fitflag = 3)
690 
691  float sum=0.;
692  for(int i=0; i<10; i++)sum=sum+_mei[11].first->GetBinContent(i+1);
693  if(sum>100){
694  if(m_fitflag==2 || m_fitflag==4){
695  float timmean=_mei[11].first->GetMean(); // let's use Phil's way instead
696  float timmeancorr=BinsizeCorr(timmean);
697  _mei[12].first->Fill(timmeancorr);
698  }
699  _mei[16].first->Fill(_mei[11].first->Integral()); // Integrated charge (may be more usfull to convert to Energy first?)
700  if(m_fitflag==3 || m_fitflag==4){
701  _mei[11].first->Fit("landau","Q");
702  TF1 *fit = _mei[11].first->GetFunction("landau");
703  _mei[13].first->Fill(fit->GetParameter(1));
704  _mei[14].first->Fill(fit->GetParError(1));
705  _mei[15].first->Fill(fit->GetChisquare()/fit->GetNDF());
706  }
707  }
708 
709 }
int adc(sample_type sample)
get the ADC sample (12 bits)
std::vector< bool > state
int size() const
total number of samples in the digi
Definition: HBHEDataFrame.h:26
const HcalPedestal * m_ped
const HcalQIECoder * m_coder
float getValue(int fCapId) const
get value for capId = 0..3
Definition: HcalPedestal.h:21
int k[5][pyjets_maxn]
float BinsizeCorr(float time)
const HcalQIECoder * getHcalCoder(const HcalGenericDetId &fId) const
const HcalQIEShape * getHcalShape(const HcalGenericDetId &fId) const
const HcalQIEShape * m_shape
const HcalPedestal * getPedestal(const HcalGenericDetId &fId) const
std::map< HcalDetId, std::map< int, LEDBUNCH > >::iterator _meol
float charge(const HcalQIEShape &fShape, unsigned fAdc, unsigned fCapId) const
ADC [0..127] + capid [0..3] -> fC conversion.
Definition: HcalQIECoder.cc:22
void HcalLedAnalysis::LedHFHists ( const HcalDetId detid,
const HFDataFrame ledDigi,
std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT,
const HcalDbService cond 
)
private

Definition at line 776 of file HcalLedAnalysis.cc.

References ecalMGPA::adc(), plotBeamSpotDB::first, HcalDbService::getHcalCoder(), HcalDbService::getHcalShape(), HcalDbService::getPedestal(), mps_fire::i, createfilelist::int, gen::k, and HFDataFrame::size().

776  {
777 
778  map<int,LEDBUNCH> _mei;
779  _meol = toolT.find(detid);
780  _mei = _meol->second;
781  // Rest the histos if we're at the end of a 'bunch'
782  if((evt-1)%m_nevtsample==0 && state[0]){
783  for(int k=0; k<(int)state.size();k++) state[k]=false;
784  for(int i=0; i<16; i++) _mei[i].first->Reset();
785  }
786 
787  // now we have the signal in fC, let's get rid of that darn pedestal
788  // Most of this is borrowed from HcalSimpleReconstructor, so thanks Jeremy/Phil
789 
790  // int maxTS = -1;
791  float max_fC = 0;
792  float ta = 0;
793  m_coder = cond.getHcalCoder(detid);
794  m_ped = cond.getPedestal(detid);
795  m_shape = cond.getHcalShape(m_coder);
796  //cout << "New Digi!!!!!!!!!!!!!!!!!!!!!!" << endl;
797  for (int TS = m_startTS; TS < m_endTS && TS < ledDigi.size(); TS++){
798  int capid = ledDigi[TS].capid();
799  // BE CAREFUL: this is assuming peds are stored in ADCs
800  int adc = (int)(ledDigi[TS].adc() - m_ped->getValue(capid));
801  if (adc < 0){ adc = 0; } // to prevent negative adcs after ped subtraction, which should really only happen
802  // if you're using the wrong peds.
803  double fC = m_coder->charge(*m_shape,adc,capid);
804  //ta = (fC - m_ped->getValue(capid));
805  ta = fC;
806  //cout << "DetID: " << detid << " CapID: " << capid << " ADC: " << adc << " Ped: " << m_ped->getValue(capid) << " fC: " << fC << endl;
807  _mei[TS].first->Fill(ta);
808  _mei[10].first->AddBinContent(TS+1,ta); // This is average pulse, could probably do better (Profile?)
809  if(m_fitflag>1){
810  if(TS==m_startTS)_mei[11].first->Reset();
811  _mei[11].first->SetBinContent(TS+1,ta);
812  }
813 
814  // keep track of max TS and max amplitude (in fC)
815  if (ta > max_fC){
816  max_fC = ta;
817  // maxTS = TS;
818  }
819  }
820 
821  // Now we have a sample with pedestals subtracted and in units of fC
822  // If we are using a weighted mean (m_fitflag = 2) to extraxt timing
823  // we now want to use Phil's timing correction. This is not necessary
824  // if we are performing a Landau fit (m_fitflag = 3)
825 
826  float sum=0.;
827  for(int i=0; i<10; i++)sum=sum+_mei[11].first->GetBinContent(i+1);
828  if(sum>100){
829  if(m_fitflag==2 || m_fitflag==4){
830  float timmean=_mei[11].first->GetMean(); // let's use Phil's way instead
831  float timmeancorr=BinsizeCorr(timmean);
832  _mei[12].first->Fill(timmeancorr);
833  }
834  _mei[16].first->Fill(_mei[11].first->Integral()); // Integrated charge (may be more usfull to convert to Energy first?)
835  if(m_fitflag==3 || m_fitflag==4){
836  _mei[11].first->Fit("landau","Q");
837  TF1 *fit = _mei[11].first->GetFunction("landau");
838  _mei[13].first->Fill(fit->GetParameter(1));
839  _mei[14].first->Fill(fit->GetParError(1));
840  _mei[15].first->Fill(fit->GetChisquare()/fit->GetNDF());
841  }
842  }
843 
844 
845 
846 }
int adc(sample_type sample)
get the ADC sample (12 bits)
std::vector< bool > state
const HcalPedestal * m_ped
const HcalQIECoder * m_coder
float getValue(int fCapId) const
get value for capId = 0..3
Definition: HcalPedestal.h:21
int k[5][pyjets_maxn]
float BinsizeCorr(float time)
int size() const
total number of samples in the digi
Definition: HFDataFrame.h:26
const HcalQIECoder * getHcalCoder(const HcalGenericDetId &fId) const
const HcalQIEShape * getHcalShape(const HcalGenericDetId &fId) const
const HcalQIEShape * m_shape
const HcalPedestal * getPedestal(const HcalGenericDetId &fId) const
std::map< HcalDetId, std::map< int, LEDBUNCH > >::iterator _meol
float charge(const HcalQIEShape &fShape, unsigned fAdc, unsigned fCapId) const
ADC [0..127] + capid [0..3] -> fC conversion.
Definition: HcalQIECoder.cc:22
void HcalLedAnalysis::LedHOHists ( const HcalDetId detid,
const HODataFrame ledDigi,
std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT,
const HcalDbService cond 
)
private

Definition at line 712 of file HcalLedAnalysis.cc.

References ecalMGPA::adc(), plotBeamSpotDB::first, HcalDbService::getHcalCoder(), HcalDbService::getHcalShape(), HcalDbService::getPedestal(), mps_fire::i, createfilelist::int, gen::k, and HODataFrame::size().

712  {
713 
714  map<int,LEDBUNCH> _mei;
715  _meol = toolT.find(detid);
716  _mei = _meol->second;
717  // Rest the histos if we're at the end of a 'bunch'
718  if((evt-1)%m_nevtsample==0 && state[0]){
719  for(int k=0; k<(int)state.size();k++) state[k]=false;
720  for(int i=0; i<16; i++) _mei[i].first->Reset();
721  }
722 
723  // now we have the signal in fC, let's get rid of that darn pedestal
724  // Most of this is borrowed from HcalSimpleReconstructor, so thanks Jeremy/Phil
725 
726  // int maxTS = -1;
727  float max_fC = 0;
728  float ta = 0;
729  m_coder = cond.getHcalCoder(detid);
730  m_ped = cond.getPedestal(detid);
731  m_shape = cond.getHcalShape(m_coder);
732  for (int TS = m_startTS; TS < m_endTS && TS < ledDigi.size(); TS++){
733  int capid = ledDigi[TS].capid();
734  int adc = ledDigi[TS].adc();
735  double fC = m_coder->charge(*m_shape,adc,capid);
736  ta = (fC - m_ped->getValue(capid));
737  _mei[TS].first->Fill(ta);
738  _mei[10].first->AddBinContent(TS+1,ta); // This is average pulse, could probably do better (Profile?)
739  if(m_fitflag>1){
740  if(TS==m_startTS)_mei[11].first->Reset();
741  _mei[11].first->SetBinContent(TS+1,ta);
742  }
743  // keep track of max TS and max amplitude (in fC)
744  if (ta > max_fC){
745  max_fC = ta;
746  // maxTS = TS;
747  }
748  }
749 
750  // Now we have a sample with pedestals subtracted and in units of fC
751  // If we are using a weighted mean (m_fitflag = 2) to extraxt timing
752  // we now want to use Phil's timing correction. This is not necessary
753  // if we are performing a Landau fit (m_fitflag = 3)
754 
755  float sum=0.;
756  for(int i=0; i<10; i++)sum=sum+_mei[11].first->GetBinContent(i+1);
757  if(sum>100){
758  if(m_fitflag==2 || m_fitflag==4){
759  float timmean=_mei[11].first->GetMean(); // let's use Phil's way instead
760  float timmeancorr=BinsizeCorr(timmean);
761  _mei[12].first->Fill(timmeancorr);
762  }
763  _mei[16].first->Fill(_mei[11].first->Integral()); // Integrated charge (may be more usfull to convert to Energy first?)
764  if(m_fitflag==3 || m_fitflag==4){
765  _mei[11].first->Fit("landau","Q");
766  TF1 *fit = _mei[11].first->GetFunction("landau");
767  _mei[13].first->Fill(fit->GetParameter(1));
768  _mei[14].first->Fill(fit->GetParError(1));
769  _mei[15].first->Fill(fit->GetChisquare()/fit->GetNDF());
770  }
771  }
772 
773 }
int adc(sample_type sample)
get the ADC sample (12 bits)
std::vector< bool > state
const HcalPedestal * m_ped
const HcalQIECoder * m_coder
int size() const
total number of samples in the digi
Definition: HODataFrame.h:27
float getValue(int fCapId) const
get value for capId = 0..3
Definition: HcalPedestal.h:21
int k[5][pyjets_maxn]
float BinsizeCorr(float time)
const HcalQIECoder * getHcalCoder(const HcalGenericDetId &fId) const
const HcalQIEShape * getHcalShape(const HcalGenericDetId &fId) const
const HcalQIEShape * m_shape
const HcalPedestal * getPedestal(const HcalGenericDetId &fId) const
std::map< HcalDetId, std::map< int, LEDBUNCH > >::iterator _meol
float charge(const HcalQIEShape &fShape, unsigned fAdc, unsigned fCapId) const
ADC [0..127] + capid [0..3] -> fC conversion.
Definition: HcalQIECoder.cc:22
void HcalLedAnalysis::LedSampleAnalysis ( )

Definition at line 425 of file HcalLedAnalysis.cc.

References simplePhotonAnalyzer_cfi::sample.

425  {
426  // it is called every m_nevtsample events (a sample) and the end of run
427  char LedSampleNum[20];
428 
429  snprintf(LedSampleNum, sizeof LedSampleNum, "LedSample_%d", sample);
430  m_file->cd();
431  m_file->mkdir(LedSampleNum);
432  m_file->cd(LedSampleNum);
433 
434 // Compute LED constants for each HB/HE, HO, HF
435  GetLedConst(hbHists.LEDTRENDS);
436  GetLedConst(hoHists.LEDTRENDS);
437  GetLedConst(hfHists.LEDTRENDS);
438 }
struct HcalLedAnalysis::@56 hbHists
void GetLedConst(std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT)
struct HcalLedAnalysis::@56 hoHists
struct HcalLedAnalysis::@56 hfHists
void HcalLedAnalysis::LedSetup ( const std::string &  m_outputFileROOT)

Definition at line 173 of file HcalLedAnalysis.cc.

173  {
174  // open the histogram file, create directories within
175  m_file=new TFile(m_outputFileROOT.c_str(),"RECREATE");
176  m_file->mkdir("HBHE");
177  m_file->cd();
178  m_file->mkdir("HO");
179  m_file->cd();
180  m_file->mkdir("HF");
181  m_file->cd();
182  m_file->mkdir("Calib");
183  m_file->cd();
184 }
std::string m_outputFileROOT
void HcalLedAnalysis::LedTrendings ( std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT)
private

Definition at line 441 of file HcalLedAnalysis.cc.

References create_public_pileup_plots::bins, HcalDetId::depth(), objects.autophobj::float, HcalDetId::ieta(), HcalDetId::iphi(), and dataset::name.

442 {
443 
444  for(_meol=toolT.begin(); _meol!=toolT.end(); _meol++){
445  char name[1024];
446  HcalDetId detid = _meol->first;
447  snprintf(name, sizeof name, "LED timing trend, eta=%d phi=%d depth=%d", detid.ieta(), detid.iphi(), detid.depth());
448  int bins = _meol->second[10+m_fitflag].second.first[0].size();
449  float lo =0.5;
450  float hi = (float)bins+0.5;
451  _meol->second[10+m_fitflag].second.second.push_back(new TH1F(name,name,bins,lo,hi));
452 
453  std::vector<double>::iterator sample_it;
454 // LED timing - put content and errors
455  int j=0;
456  for(sample_it=_meol->second[10+m_fitflag].second.first[0].begin();
457  sample_it!=_meol->second[10+m_fitflag].second.first[0].end();++sample_it){
458  _meol->second[10+m_fitflag].second.second[0]->SetBinContent(++j,*sample_it);
459  }
460  j=0;
461  for(sample_it=_meol->second[10+m_fitflag].second.first[1].begin();
462  sample_it!=_meol->second[10+m_fitflag].second.first[1].end();++sample_it){
463  _meol->second[10+m_fitflag].second.second[0]->SetBinError(++j,*sample_it);
464  }
465  snprintf(name, sizeof name, "Sample (%d events)", m_nevtsample);
466  _meol->second[10+m_fitflag].second.second[0]->GetXaxis()->SetTitle(name);
467  _meol->second[10+m_fitflag].second.second[0]->GetYaxis()->SetTitle("Peak position");
468  _meol->second[10+m_fitflag].second.second[0]->Write();
469  }
470 }
int depth() const
get the tower depth
Definition: HcalDetId.cc:108
int ieta() const
get the cell ieta
Definition: HcalDetId.h:56
int iphi() const
get the cell iphi
Definition: HcalDetId.cc:103
std::map< HcalDetId, std::map< int, LEDBUNCH > >::iterator _meol
void HcalLedAnalysis::ProcessCalibEvent ( int  fiberChan,
HcalCalibDetId  calibId,
const HcalCalibDataFrame digi 
)
private

Definition at line 895 of file HcalLedAnalysis.cc.

References HcalQIESample::adc(), HcalCalibDetId::calibFlavor(), HcalCalibDetId::CalibrationBox, HcalCalibDetId::cboxChannelString(), HcalBarrel, HcalEndcap, HcalForward, HcalOuter, HcalCalibDetId::hcalSubdet(), mps_fire::i, HcalCalibDetId::ieta(), HcalCalibDetId::iphi(), dataset::name, tablePrinter::prefix, HcalCalibDataFrame::sample(), HcalCalibDataFrame::size(), and AlCaHLTBitMon_QueryRunRegistry::string.

895  {
896 
897  _meca = calibHists.find(calibId);
898  if (_meca==calibHists.end()){
899  // if histos for this channel do not exist, first create them
900  char name[1024];
903  std::string sector=(calibId.hcalSubdet()==HcalBarrel)?("HB"):
904  (calibId.hcalSubdet()==HcalEndcap)?("HE"):
905  (calibId.hcalSubdet()==HcalOuter)?("HO"):
906  (calibId.hcalSubdet()==HcalForward)?("HF"):"";
907  snprintf(name, sizeof name, "%s %+d iphi=%d %s", sector.c_str(), calibId.ieta(), calibId.iphi(), calibId.cboxChannelString().c_str());
908  prefix=name;
909  }
910 
911  snprintf(name, sizeof name, "%s Pin Diode Mean", prefix.c_str());
912  calibHists[calibId].avePulse = new TProfile(name,name,10,-0.5,9.5,0,1000);
913  snprintf(name, sizeof name, "%s Pin Diode Current Pulse", prefix.c_str());
914  calibHists[calibId].thisPulse = new TH1F(name,name,10,-0.5,9.5);
915  snprintf(name, sizeof name, "%s Pin Diode Integrated Pulse", prefix.c_str());
916  calibHists[calibId].integPulse = new TH1F(name,name,200,0,500);
917  }
918  else {
919  for (int i=m_startTS; i<digi.size() && i<=m_endTS; i++) {
920  calibHists[calibId].avePulse->Fill(i,digi.sample(i).adc());
921  calibHists[calibId].thisPulse->SetBinContent(i+1,digi.sample(i).adc());
922  }
923  calibHists[calibId].integPulse->Fill(calibHists[calibId].thisPulse->Integral());
924  }
925 }
CalibDetType calibFlavor() const
get the flavor of this calibration detid
std::map< HcalCalibDetId, CALIBBUNCH > calibHists
int adc() const
get the ADC sample
Definition: HcalQIESample.h:22
int ieta() const
get the rbx name (if relevant)
int size() const
total number of samples in the digi
std::string cboxChannelString() const
get the calibration box channel as a string (if relevant)
std::map< HcalCalibDetId, CALIBBUNCH >::iterator _meca
const HcalQIESample & sample(int i) const
access a sample
int iphi() const
get the low-edge iphi (if relevant)
HcalSubdetector hcalSubdet() const
get the HcalSubdetector (if relevant)
void HcalLedAnalysis::processLedEvent ( const HBHEDigiCollection hbhe,
const HODigiCollection ho,
const HFDigiCollection hf,
const HcalCalibDigiCollection calib,
const HcalDbService cond 
)

Definition at line 526 of file HcalLedAnalysis.cc.

References edm::SortedCollection< T, SORT >::begin(), HcalCalibDataFrame::elecId(), edm::SortedCollection< T, SORT >::empty(), edm::SortedCollection< T, SORT >::end(), HcalElectronicsId::fiberChanId(), mps_fire::i, HFDataFrame::id(), HBHEDataFrame::id(), HcalCalibDataFrame::id(), HODataFrame::id(), createfilelist::int, gen::k, simplePhotonAnalyzer_cfi::sample, and edm::SortedCollection< T, SORT >::size().

531 {
532  evt++;
533  sample = (evt-1)/m_nevtsample +1;
536 
537  // Calib
538 
539  if (m_usecalib){
540  try{
541  if(calib.empty()) throw (int)calib.size();
542  // this is effectively a loop over electronic channels
543  for (HcalCalibDigiCollection::const_iterator j=calib.begin(); j!=calib.end(); ++j){
544  const HcalCalibDataFrame digi = (const HcalCalibDataFrame)(*j);
545  HcalElectronicsId elecId = digi.elecId();
546  HcalCalibDetId calibId = digi.id();
547  ProcessCalibEvent(elecId.fiberChanId(),calibId,digi); //Shouldn't depend on anything in elecId but not sure how else to do it
548  }
549  }
550  catch (int i ) {
551  // m_logFile<< "Event with " << i<<" Calib Digis passed." << std::endl;
552  }
553  }
554 
555 
556  // HB + HE
557  try{
558  if(hbhe.empty()) throw (int)hbhe.size();
559 // this is effectively a loop over electronic channels
560  for (HBHEDigiCollection::const_iterator j=hbhe.begin(); j!=hbhe.end(); ++j){
561  const HBHEDataFrame digi = (const HBHEDataFrame)(*j);
562  for(int k=0; k<(int)state.size();k++) state[k]=true;
563  // See if histos exist for this channel, and if not, create them
564  _meol = hbHists.LEDTRENDS.find(digi.id());
565  if (_meol==hbHists.LEDTRENDS.end()){
566  SetupLEDHists(0,digi.id(),hbHists.LEDTRENDS);
567  }
568  LedHBHEHists(digi.id(),digi,hbHists.LEDTRENDS,cond);
569  }
570  }
571  catch (int i ) {
572 // m_logFile<< "Event with " << i<<" HBHE Digis passed." << std::endl;
573  }
574 
575  // HO
576  try{
577  if(ho.empty()) throw (int)ho.size();
578  for (HODigiCollection::const_iterator j=ho.begin(); j!=ho.end(); ++j){
579  const HODataFrame digi = (const HODataFrame)(*j);
580  _meol = hoHists.LEDTRENDS.find(digi.id());
581  if (_meol==hoHists.LEDTRENDS.end()){
582  SetupLEDHists(1,digi.id(),hoHists.LEDTRENDS);
583  }
584  LedHOHists(digi.id(),digi,hoHists.LEDTRENDS,cond);
585  }
586  }
587  catch (int i ) {
588 // m_logFile << "Event with " << i<<" HO Digis passed." << std::endl;
589  }
590 
591  // HF
592  try{
593  if(hf.empty()) throw (int)hf.size();
594  for (HFDigiCollection::const_iterator j=hf.begin(); j!=hf.end(); ++j){
595  const HFDataFrame digi = (const HFDataFrame)(*j);
596  _meol = hfHists.LEDTRENDS.find(digi.id());
597  if (_meol==hfHists.LEDTRENDS.end()){
598  SetupLEDHists(2,digi.id(),hfHists.LEDTRENDS);
599  }
600  LedHFHists(digi.id(),digi,hfHists.LEDTRENDS,cond);
601  }
602  }
603  catch (int i ) {
604 // m_logFile << "Event with " << i<<" HF Digis passed." << std::endl;
605  }
606 
607  // Call the function every m_nevtsample events
609 
610 }
void LedHBHEHists(const HcalDetId &detid, const HBHEDataFrame &ledDigi, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT, const HcalDbService &cond)
std::vector< bool > state
std::vector< HcalCalibDataFrame >::const_iterator const_iterator
const HcalDetId & id() const
Definition: HODataFrame.h:23
const HcalElectronicsId & elecId() const
struct HcalLedAnalysis::@56 hbHists
void SetupLEDHists(int id, const HcalDetId detid, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT)
void ProcessCalibEvent(int fiberChan, HcalCalibDetId calibId, const HcalCalibDataFrame &digi)
const HcalCalibDetId & id() const
struct HcalLedAnalysis::@56 hoHists
int fiberChanId() const
get the fiber channel id (which of channels on a fiber)
int k[5][pyjets_maxn]
const_iterator end() const
void LedHFHists(const HcalDetId &detid, const HFDataFrame &ledDigi, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT, const HcalDbService &cond)
struct HcalLedAnalysis::@56 hfHists
size_type size() const
const HcalDetId & id() const
Definition: HBHEDataFrame.h:22
void LedHOHists(const HcalDetId &detid, const HODataFrame &ledDigi, std::map< HcalDetId, std::map< int, LEDBUNCH > > &toolT, const HcalDbService &cond)
const HcalDetId & id() const
Definition: HFDataFrame.h:22
Readout chain identification for Hcal.
const_iterator begin() const
std::map< HcalDetId, std::map< int, LEDBUNCH > >::iterator _meol
void HcalLedAnalysis::SetupLEDHists ( int  id,
const HcalDetId  detid,
std::map< HcalDetId, std::map< int, LEDBUNCH > > &  toolT 
)
private

Definition at line 612 of file HcalLedAnalysis.cc.

References HcalDetId::depth(), mps_fire::i, HcalDetId::ieta(), edm::eventsetup::heterocontainer::insert(), HcalDetId::iphi(), and dataset::name.

612  {
613 
614  string type = "HBHE";
615  if(id==1) type = "HO";
616  if(id==2) type = "HF";
617 
618  _meol = toolT.find(detid);
619  if (_meol==toolT.end()){
620 // if histos for this channel do not exist, create them
621  map<int,LEDBUNCH> insert;
622  char name[1024];
623  for(int i=0; i<10; i++){
624  snprintf(name, sizeof name, "%s Pulse height, eta=%d phi=%d depth=%d TS=%d", type.c_str(), detid.ieta(), detid.iphi(), detid.depth(), i);
625  insert[i].first = new TH1F(name,name,200,0.,2000.);
626  }
627  snprintf(name, sizeof name, "%s LED Mean pulse, eta=%d phi=%d depth=%d", type.c_str(), detid.ieta(), detid.iphi(), detid.depth());
628  insert[10].first = new TH1F(name,name,10,-0.5,9.5);
629  snprintf(name, sizeof name, "%s LED Pulse, eta=%d phi=%d depth=%d", type.c_str(), detid.ieta(), detid.iphi(), detid.depth());
630  insert[11].first = new TH1F(name,name,10,-0.5,9.5);
631  snprintf(name, sizeof name, "%s Mean TS, eta=%d phi=%d depth=%d", type.c_str(), detid.ieta(), detid.iphi(), detid.depth());
632  insert[12].first = new TH1F(name,name,200,0.,10.);
633  snprintf(name, sizeof name, "%s Peak TS, eta=%d phi=%d depth=%d", type.c_str(), detid.ieta(), detid.iphi(), detid.depth());
634  insert[13].first = new TH1F(name,name,200,0.,10.);
635  snprintf(name, sizeof name, "%s Peak TS error, eta=%d phi=%d depth=%d", type.c_str(), detid.ieta(), detid.iphi(), detid.depth());
636  insert[14].first = new TH1F(name,name,200,0.,0.05);
637  snprintf(name, sizeof name, "%s Fit chi2, eta=%d phi=%d depth=%d",type.c_str(),detid.ieta(),detid.iphi(),detid.depth());
638  insert[15].first = new TH1F(name,name,100,0.,50.);
639  snprintf(name, sizeof name, "%s Integrated Signal, eta=%d phi=%d depth=%d", type.c_str(), detid.ieta(), detid.iphi(), detid.depth());
640  insert[16].first = new TH1F(name,name,500,0.,5000.);
641 
642  toolT[detid] = insert;
643  }
644 }
type
Definition: HCALResponse.h:21
int depth() const
get the tower depth
Definition: HcalDetId.cc:108
int ieta() const
get the cell ieta
Definition: HcalDetId.h:56
bool insert(Storage &iStorage, ItemType *iItem, const IdTag &iIdTag)
Definition: HCMethods.h:49
int iphi() const
get the cell iphi
Definition: HcalDetId.cc:103
std::map< HcalDetId, std::map< int, LEDBUNCH > >::iterator _meol

Member Data Documentation

std::map<HcalCalibDetId,CALIBBUNCH>::iterator HcalLedAnalysis::_meca
private

Definition at line 121 of file HcalLedAnalysis.h.

std::map<HcalDetId,std::map<int,float> >::iterator HcalLedAnalysis::_meee
private

Definition at line 118 of file HcalLedAnalysis.h.

std::map<HcalDetId,std::map<int, LEDBUNCH > >::iterator HcalLedAnalysis::_meol
private

Definition at line 116 of file HcalLedAnalysis.h.

TH1F* HcalLedAnalysis::ALLLEDS

Definition at line 111 of file HcalLedAnalysis.h.

std::map<HcalCalibDetId,CALIBBUNCH> HcalLedAnalysis::calibHists
private

Definition at line 120 of file HcalLedAnalysis.h.

TH1F* HcalLedAnalysis::CHI2

Definition at line 114 of file HcalLedAnalysis.h.

int HcalLedAnalysis::evt
private

Definition at line 124 of file HcalLedAnalysis.h.

int HcalLedAnalysis::evt_curr
private

Definition at line 126 of file HcalLedAnalysis.h.

struct { ... } HcalLedAnalysis::hbHists
struct { ... } HcalLedAnalysis::hfHists
struct { ... } HcalLedAnalysis::hoHists
TH1F* HcalLedAnalysis::LEDMEAN

Definition at line 113 of file HcalLedAnalysis.h.

TH1F* HcalLedAnalysis::LEDRMS

Definition at line 112 of file HcalLedAnalysis.h.

std::map<HcalDetId,std::map<int, LEDBUNCH > > HcalLedAnalysis::LEDTRENDS

Definition at line 110 of file HcalLedAnalysis.h.

std::map<HcalDetId,std::map<int,float> > HcalLedAnalysis::m_AllPedVals
private

Definition at line 117 of file HcalLedAnalysis.h.

const HcalQIECoder* HcalLedAnalysis::m_coder
private

Definition at line 107 of file HcalLedAnalysis.h.

int HcalLedAnalysis::m_endTS
private

Definition at line 92 of file HcalLedAnalysis.h.

TFile* HcalLedAnalysis::m_file
private

Definition at line 74 of file HcalLedAnalysis.h.

int HcalLedAnalysis::m_fitflag
private

Definition at line 104 of file HcalLedAnalysis.h.

int HcalLedAnalysis::m_hiSaveflag
private

Definition at line 94 of file HcalLedAnalysis.h.

std::ofstream HcalLedAnalysis::m_logFile
private

Definition at line 88 of file HcalLedAnalysis.h.

int HcalLedAnalysis::m_nevtsample
private

Definition at line 93 of file HcalLedAnalysis.h.

std::ofstream HcalLedAnalysis::m_outFile
private

Definition at line 87 of file HcalLedAnalysis.h.

std::string HcalLedAnalysis::m_outputFileROOT
private

Definition at line 84 of file HcalLedAnalysis.h.

std::string HcalLedAnalysis::m_outputFileText
private

Definition at line 85 of file HcalLedAnalysis.h.

std::string HcalLedAnalysis::m_outputFileX
private

Definition at line 86 of file HcalLedAnalysis.h.

std::ofstream HcalLedAnalysis::m_outputFileXML
private

Definition at line 89 of file HcalLedAnalysis.h.

const HcalPedestal* HcalLedAnalysis::m_ped
private

Definition at line 108 of file HcalLedAnalysis.h.

const HcalQIEShape* HcalLedAnalysis::m_shape
private

Definition at line 106 of file HcalLedAnalysis.h.

int HcalLedAnalysis::m_startTS
private

Definition at line 91 of file HcalLedAnalysis.h.

bool HcalLedAnalysis::m_usecalib
private

Definition at line 95 of file HcalLedAnalysis.h.

int HcalLedAnalysis::sample
private

Definition at line 125 of file HcalLedAnalysis.h.

Referenced by svgfig.Curve::Path().

std::vector<bool> HcalLedAnalysis::state
private